2011
DOI: 10.1002/app.34706
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Solid‐state structural evolution of poly(ethylene terephthalate) during step uniaxial stretching from different initial morphologies: An in situ wide angle x‐ray scattering study

Abstract: This work reports an in situ wide-angle Xray scattering (WAXS) study of the structural evolution of PET with distinct initial morphologies during step uniaxial stretching in the solid state. Two types of samples were analyzed under synchrotron X-ray radiation, namely quasi-amorphous (QA) and semicrystalline (SC) (with 2D and 3D order). Results show that initially different QA morphologies evolve following the same stages: (i) stage I (before neck), at almost constant orientation level the amorphous phase evolv… Show more

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Cited by 9 publications
(6 citation statements)
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“…Homogeneous stress-strain curve and selected 2D WAXS patterns for solid state uniaxial stretching of neat PET (note: a mismatch in the WAXD patterns is observed on the neck region due to neck formation out of the incident X-ray point). 39 At this stage of deformation samples morphologies were considered to be composed of three phases: (i) amorphous (ii) mesophase, and (iii) periodical mesophasemesophase with conformational periodicity perpendicular to the stretching direction. Such accumulation time was set as a lowest as possible for considered strain rate.…”
Section: Simultaneous Deformation and In Situ Synchrotron Characterizmentioning
confidence: 99%
See 1 more Smart Citation
“…Homogeneous stress-strain curve and selected 2D WAXS patterns for solid state uniaxial stretching of neat PET (note: a mismatch in the WAXD patterns is observed on the neck region due to neck formation out of the incident X-ray point). 39 At this stage of deformation samples morphologies were considered to be composed of three phases: (i) amorphous (ii) mesophase, and (iii) periodical mesophasemesophase with conformational periodicity perpendicular to the stretching direction. Such accumulation time was set as a lowest as possible for considered strain rate.…”
Section: Simultaneous Deformation and In Situ Synchrotron Characterizmentioning
confidence: 99%
“…As the strain increases, the WAXS patterns can exhibit a pair of meridional mesomorphic reflection ð103Þ at about 2H ¼ 25.8 , 37,38 indicating conformational regularity, and called periodical mesophase, PM. 39 At this stage of deformation samples morphologies were considered to be composed of three phases: (i) amorphous (ii) mesophase, and (iii) periodical mesophasemesophase with conformational periodicity perpendicular to the stretching direction. The area of fitted ð103Þ peak profile was used to determine the mass fraction of the PM.…”
Section: Simultaneous Deformation and In Situ Synchrotron Characterizmentioning
confidence: 99%
“…Equipmental setups were as follows: WAXS: Sample‐to‐detector distance of 145 mm and 2D WAXS patterns were acquired with accumulation time of 20 s. Samples were stretched at a constant cross‐head velocity of 2 mm min −1 (strain rate of 0.002 s −1 ). Such accumulation time was set as a lowest as possible for considered strain rate . WAXS was calibrated by means of a crystalline PET sample. SAXS: Sample‐to‐detector distance of 3025 mm and 2D SAXS patterns were acquired with accumulation time of 30 s. Samples were stretched at a constant cross‐head velocity of 5 mm min −1 (strain rate of 0.006 s −1 ). …”
Section: Methodsmentioning
confidence: 99%
“…The mass fractions of the individual phases were taken as the ratio of the area for each phase to the total area of the equatorial profile. As the strain increases, the WAXS patterns can exhibit a pair of meridional mesomorphic reflection (103true¯) at about 2θ = 25.8°, indicating conformational regularity, and called PM . At this stage of deformation, the morphologies of the samples were considered to be composed of three phases: (i) amorphous, (ii) mesophase, and (iii) PM, mesophase with conformational periodicity perpendicular to the stretching direction.…”
Section: Methodsmentioning
confidence: 99%
“…The drawing behavior of PET has been studied extensively over many years and different workers have highlighted different features, from the purely mechanical aspects to the structural changes [1][2][3][4][5][6][7][8][9][10][11][12][13] . When PET fiber structure is deformed by hot multistage drawing process, individual crystalline regions slide past each other, to take up a new position, where they are held together just as strong as in the origin material, owing to the formation of fresh, inter-atomic bonds.…”
Section: Introductionmentioning
confidence: 99%